EP0567579B1 - Modular unit for a tubular ultrasonic reactor - Google Patents

Modular unit for a tubular ultrasonic reactor Download PDF

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Publication number
EP0567579B1
EP0567579B1 EP92904795A EP92904795A EP0567579B1 EP 0567579 B1 EP0567579 B1 EP 0567579B1 EP 92904795 A EP92904795 A EP 92904795A EP 92904795 A EP92904795 A EP 92904795A EP 0567579 B1 EP0567579 B1 EP 0567579B1
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EP
European Patent Office
Prior art keywords
collar
tubular
ultrasonic
converter
frequency
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EP92904795A
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German (de)
French (fr)
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EP0567579A1 (en
Inventor
Philippe Vaxelaire
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Sodeva
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VAXELAIRE Philippe
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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61LMETHODS OR APPARATUS FOR STERILISING MATERIALS OR OBJECTS IN GENERAL; DISINFECTION, STERILISATION OR DEODORISATION OF AIR; CHEMICAL ASPECTS OF BANDAGES, DRESSINGS, ABSORBENT PADS OR SURGICAL ARTICLES; MATERIALS FOR BANDAGES, DRESSINGS, ABSORBENT PADS OR SURGICAL ARTICLES
    • A61L2/00Methods or apparatus for disinfecting or sterilising materials or objects other than foodstuffs or contact lenses; Accessories therefor
    • A61L2/02Methods or apparatus for disinfecting or sterilising materials or objects other than foodstuffs or contact lenses; Accessories therefor using physical phenomena
    • A61L2/025Ultrasonics
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01DSEPARATION
    • B01D19/00Degasification of liquids
    • B01D19/0073Degasification of liquids by a method not covered by groups B01D19/0005 - B01D19/0042
    • B01D19/0078Degasification of liquids by a method not covered by groups B01D19/0005 - B01D19/0042 by vibration
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01FMIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
    • B01F31/00Mixers with shaking, oscillating, or vibrating mechanisms
    • B01F31/80Mixing by means of high-frequency vibrations above one kHz, e.g. ultrasonic vibrations
    • B01F31/84Mixing by means of high-frequency vibrations above one kHz, e.g. ultrasonic vibrations for material continuously moving through a tube, e.g. by deforming the tube
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01JCHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
    • B01J19/00Chemical, physical or physico-chemical processes in general; Their relevant apparatus
    • B01J19/08Processes employing the direct application of electric or wave energy, or particle radiation; Apparatus therefor
    • B01J19/10Processes employing the direct application of electric or wave energy, or particle radiation; Apparatus therefor employing sonic or ultrasonic vibrations
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B06GENERATING OR TRANSMITTING MECHANICAL VIBRATIONS IN GENERAL
    • B06BMETHODS OR APPARATUS FOR GENERATING OR TRANSMITTING MECHANICAL VIBRATIONS OF INFRASONIC, SONIC, OR ULTRASONIC FREQUENCY, e.g. FOR PERFORMING MECHANICAL WORK IN GENERAL
    • B06B3/00Methods or apparatus specially adapted for transmitting mechanical vibrations of infrasonic, sonic, or ultrasonic frequency

Definitions

  • the present invention relates to a modular tubular ultrasonic reactor unit as well as the various associations of these so-called units with a view to forming multi-reactors adapted to each particular type of application.
  • the vibration of the bottom of the tank induces in the liquid contained the cavitation phenomenon whose intensity decreases as one moves away from the source, in this case the bottom of the tank.
  • double diaphragms in opposition which, like the aforementioned cleaning technique, consists in placing a number of transmitters on two sheets of this sheet facing each other at a distance of between 1.5 and 4 mm. , called coupling distance.
  • the liquid to be treated is then passed between the two emissive plates.
  • Another configuration uses a plurality of axis transmitters at the periphery of a metal tube. This configuration certainly allows this treatment in passing but has the disadvantages of requiring a large number of transmitters, of not offering the possibility of exceeding the level of amplitude commonly obtained in cleaning technique and requires the complete replacement of the system in the event of wear of the treatment tube in contact with the treated product.
  • WO-A-82 03795 describes an installation for the acoustic degassing of liquids, but in no case does it suggest an ultrasonic tubular reactor based on the principle of mechanical resonance in order to propagate ultrasonic vibrations consistently from a reduced number of transmitters.
  • ultrasonic probes well known for example under the name of Sonify (BRANSON) or Vibracell (SONIC'S and MATERIALS). This type of device can handle low volumes or low flow rates.
  • the present invention aims to provide a tubular ultrasonic reactor based on the principle of mechanical resonance to propagate coherently from a reduced number of transmitters ultrasonic vibrations intended for the treatment of fluids passing through said reactor.
  • a modular reactor unit characterized in that it comprises a tubular metal body of cylindrical interior surface and of circular cross section, open at its two ends. supply and discharge, in that the outer surface of said tubular metallic body has, in the vicinity of the nodal zone, a ring coaxial with said tube and projecting radially, and in that at least one ultrasonic converter is arranged radially and integral with said ring at the periphery of the latter, the frequency of said converter being equal to the vibration frequency of said ring and to the longitudinal vibration frequency of said tubular metal body.
  • the unit 10 firstly comprises a tubular metallic body 12 having an inner surface 14 which is cylindrical and of circular cross section.
  • the tubular metal body 12 is open at its two ends, that is to say respectively at its supply end 16 and at its discharge end 18.
  • the flow of the materials and / or of the reagents to be treated flows therefore in the direction of the arrow going from the end 16 towards the end 18.
  • These two supply and discharge ends 16, 18 will be associated with supply and discharge conduits themselves possibly provided with circulation pumps.
  • the rest of the installation is not shown since it uses entirely conventional members well known to those skilled in the art.
  • the modular unit 10 also comprises, on the external surface of the tubular metallic body 12, in the vicinity of the nodal zone of the latter, a ring 20 coaxial with said tube, said ring projecting radially outwards from the free surface of the tubular body 12.
  • the modular unit 10 comprises at least one ultra-sonic converter 22 which is arranged radially and integral with said crown 20 at the periphery of the latter.
  • the frequency of said converter 22 is equal to the frequency of vibration of said ring 20 and to the frequency of longitudinal vibration of the tubular metallic body 12.
  • a conventional converter for example of the piezoelectric excitation type, is used as the ultrasonic converter 22. It can for example be of the "Langevin Triplet" type as described in the book High Intensity Ultrasonics by B. BROWN and J.E. GOODMAN.
  • the coaxial ring 20 is machined in the mass of the tubular metal body 12.
  • the ring 20 is connected to the external surface of the tubular body 12 by via connection leave 24.
  • the tubular metallic body 12 has, on the embodiment described, a length equal to half a wavelength for the frequency which it is desired to use.
  • the frequency of the ultrasonic vibration delivered by the transmitter or the converter 22 will generally be between 5 and 100 kHz.
  • the length of the tubular metal body is strictly equal to half a wavelength of the frequency of the ultrasonic vibration.
  • connection of this metallic part with the modular unit can for example be carried out at the level of the stomachs of longitudinal amplitude (stress nodes) by means of threads. press fittings, welds or the like or else be machined in the mass.
  • the inside and outside diameters of the crown 20, the inside diameter of the crown 20 moreover corresponding to the internal diameter of the tubular metallic body 12, determine the radial frequency of this coaxial crown 20.
  • the length of the tubular metallic body 12 which is chosen as a multiple of half wavelength determines the longitudinal frequency of l whole reactor.
  • a single converter or transmitter 22 is used which can be either of the electrostrictive, magnetostrictive, electrocapacitive, or even more usually piezoelectric type.
  • the converter 22 is fixed to the periphery of the crown 20 preferably at the level of a flat 26 arranged so as to ensure perfect contacting of the transmitter 22 with the crown 20.
  • the mechanical connection between these two members is in particular advantageously provided by means of a stud or the like 28.
  • the interior and exterior diameters d i and d e of the crown respectively 20 can be conventionally determined by a person skilled in the art in relation to said vibration frequency delivered by the transmitter.
  • the inside and outside diameters of the latter are determined as a function of the vibration frequency F in accordance with the relation: where C represents the speed of sound, in cm per second, associated with the metal in which said crown 20 is produced.
  • crown made of alloy aluminum excited from a 2O kHz piezoelectric transmitter with a diameter of 40 mm.
  • the crown will have a thickness of 30 mm, an outside diameter of 130 mm for an inside diameter of 42 mm to respect the frequency of 20 kHz delivered by the transmitter.
  • Such a reactor unit operates in the following manner.
  • the vibration produced by the converter (s) 22 causes the crown 20 to vibrate radially, which, at the same time, causes the tubular part to vibrate longitudinally in multiples of half the wavelength of the body tubular metal 12.
  • the compression phase of the crown 20 corresponds to the longitudinal expansion phase of the tubular body 12, and the expansion of the crown 20 corresponds to the longitudinal compression phase of the tubular body 12.
  • the coaxial ring 20 must be located in the vicinity of the nodal plane of the tubular body 12.
  • the reactor according to the invention uses the radial vibration of the internal diameter of the ring 20 to cavitate any liquid to be treated, which is found continuously delivered through the internal diameter of the metallic tubular body 12.
  • any liquid, any gas, any colloid or any other material to be treated must be by conventional means, not shown, delivered through the internal diameter 14 of the tubular metallic body 12 of the reactor 10.
  • FIG. 2 represents an ultrasonic reactor which is obtained by cutting in series a plurality of modular reactor units 10 as shown in FIGS. 1A and 1B.
  • three modular units 10 have been grouped together so as to form an online multi-reactor, but using only a single ultrasonic converter 22.
  • Such an assembly can be produced in one piece or by rigid connections of said modular units at the level of the stomachs of longitudinal amplitude.
  • the online ultrasonic reactor comprises several ultrasonic transmitters or converters 22, the latter can advantageously be supplied in parallel by the same generator. However, care should be taken to reverse the polarity of the emitters of even rank with respect to the emitters of odd rank, this in order to respect the phase inversions that occur at each half wavelength.
  • the particular embodiment represented in FIG. 4 comprises a radial crown 20 which will excite in series a length of tubular metallic body extending the tubular part of the central modular element on either side of the latter. It will be observed that the length of the tubes on each of the two sides of the central modular unit is also produced in an integer multiple of half wavelength. Said tubes can for example be screwed or force-fitted to the modular unit at the level of the bellies of longitudinal amplitude. He is not necessary to have recourse to a symmetrical arrangement. As illustrated in FIG. 4, it may be advantageous, depending on the particular applications envisaged, to provide a more or less long tubular zone upstream or downstream of the zone of intense ultrasonic vibration.
  • a multiple of half wavelength generally between 1 and 10, multiple chosen according to the material in which the reactor is made, according to the products to be treated and of course, the nature and conditions of the reaction involved in the reactor. It may for example be advantageous, as illustrated in FIG. 4, to provide a supply inlet relatively close to the intense cavitation zone, which makes it possible to rapidly communicate the energy necessary for the initiation of the reaction. which can extend into the downstream tubular part of the reactor, ie in an area subjected to ultra-sonic cavitation of less power and less amplitude.
  • FIG. 5 illustrates a final embodiment in which several radial rings 20 are used which will serially excite a length of tube which, in this case is at half wavelength, but which of course can also be formed by greater lengths of tubes produced as an integer multiple of half wavelengths.
  • the operating principle remains strictly identical.
  • the modular reactor unit is arranged so as to receive inside a tubular element 30 tuned to the frequency of the transmitter 22, vibrating from the axial mode by clamping its two ends 32,34 in the vicinity of the bellies of amplitude (constraint nodes) longitudinal of said unit.
  • tubular element 30 is clamped between two pieces which are themselves tuned to the frequency of the transmitter and which can be, for example, tubular metallic bodies 36 and 38 as described in FIG. 4.
  • the added tubular element 30 will advantageously be arranged with neat spans (ie 45 °) to ensure perfect centering and good coupling with the elements 36 and 38 clamping it at each of its ends 32 and 34. It will be noted, such that described in FIG. 7, a set 40 with the internal diameter of the modular unit allowing the free radial expansion and compression of the tubular element 30 inside which the fluid to be treated circulates.
  • the modular reactor units according to the invention can be used for the treatment of all types of liquid, gas, colloid, etc. naturally or forced flow through the inside diameter of the reactors. It should also be noted that an external liquid flow could be simultaneously treated by the cavitation caused by the external vibration of the crowns 20, that is to say that two different liquid flows could be treated simultaneously, the one passing inside the reactor, the other flowing at the outer periphery.

Abstract

PCT No. PCT/FR92/00029 Sec. 371 Date Jul. 19, 1993 Sec. 102(e) Date Jul. 19, 1993 PCT Filed Jan. 15, 1992 PCT Pub. No. WO82/00260 PCT Pub. Date Feb. 4, 1982.Modular reactor unit for continuous ultrasonic processing of substances and/or reagents, characterized in that it comprises a tubular metallic body having a cylindrical inner surface and a straight circular cross secton, open at its feed and discharge ends, in that the surface of said tubular metallic body has, in the region of its nodal zone, a radially projecting collar coaxial to said tube, and in that at least one ultrasonic converter is radially arranged integral with said collar at the periphery of the latter, the frequency of said converter being equal to the frequency of vibration of said collar and to the frequency of longitudinal vibration of said tubular metallic body.

Description

La présente invention concerne une unité modulaire de réacteur ultrasonique tubulaire ainsi que les diverses associations ces dites unités en vue de former des multiréacteurs adaptés à chaque type d'application particulière.The present invention relates to a modular tubular ultrasonic reactor unit as well as the various associations of these so-called units with a view to forming multi-reactors adapted to each particular type of application.

Dans l'état actuel de la technique on connaît divers dispositifs ultrasoniques destinés à réaliser le traitement des liquides. Il s'agit principalement de dispositifs issus de la technologie du nettoyage par ultrasons et généralement agencés sous forme de cuves métalliques ce faible épaisseur au fond desquelles sont fixés une pluralité d'émetteurs.In the current state of the art, various ultrasonic devices are known intended for carrying out the treatment of liquids. These are mainly devices derived from ultrasonic cleaning technology and generally arranged in the form of metal tanks of this small thickness at the bottom of which are fixed a plurality of transmitters.

La mise en vibration du fond de la cuve induit dans le liquide contenu le phénomène de cavitation dont l'intensité décroit à mesure qu'on s'éloigne de la source, en l'occurence le fond de la cuve.The vibration of the bottom of the tank induces in the liquid contained the cavitation phenomenon whose intensity decreases as one moves away from the source, in this case the bottom of the tank.

On connaît également une technique dite à double diaphragmes en opposition, qui, tout comme la technique de nettoyage précitée, consiste à disposer un certain nombre d'émetteurs sur deux plaques ce tôle mises en regard à une distance comprise entre 1,5 et 4 mm, appelée distance de couplage. On fait ensuite passer le liquide à traiter entre las deux plaques émissives.There is also known a technique called double diaphragms in opposition, which, like the aforementioned cleaning technique, consists in placing a number of transmitters on two sheets of this sheet facing each other at a distance of between 1.5 and 4 mm. , called coupling distance. The liquid to be treated is then passed between the two emissive plates.

Une autre configuration utilise une pluralité d'émetteurs axes à la périphérie d'un tube métallique. Cette configuration permet certes ce traiter en passage mais présente les inconvénients de nécessiter un grand nombre d'émetteurs, de ne pas offrir la possibilité de dépasser le niveau d'amplitude couramment obtenu en technique de nettoyage et impose le remplacement complet du système en cas d'usure du tube de traitement en contact avec le produit traité.Another configuration uses a plurality of axis transmitters at the periphery of a metal tube. This configuration certainly allows this treatment in passing but has the disadvantages of requiring a large number of transmitters, of not offering the possibility of exceeding the level of amplitude commonly obtained in cleaning technique and requires the complete replacement of the system in the event of wear of the treatment tube in contact with the treated product.

Toutes les techniques connues se ramènent en fait a des techniques de nettoyage par ultrasons où les émetteurs sont directement fixés à des diaphragmes métalliques, tubes ou fonds de cuve.All known techniques can be reduced to ultrasonic cleaning techniques where the emitters are directly attached to metal diaphragms, tubes or tank bottoms.

L'état de la technique peut également être illustré par WO-A-82 03795, qui décrit une installation de dégazéification acoustique de liquides, mais en aucun cas ne suggère un réacteur tubulaire ultrasonique fondé sur le principe de la résonnance mécanique en vue de propager les vibrations ultrasoniques de façon cohérente à partir d'un nombre réduit d'émetteurs.The state of the art can also be illustrated by WO-A-82 03795, which describes an installation for the acoustic degassing of liquids, but in no case does it suggest an ultrasonic tubular reactor based on the principle of mechanical resonance in order to propagate ultrasonic vibrations consistently from a reduced number of transmitters.

On connait enfin les sondes expérimentales de laboratoire dites sondes ultrasoniques bien connues par exemple sous le nom de Sonifier (BRANSON) ou Vibracell (SONIC'S et MATERIALS). Ce type d'appareils permet de traiter de faibles volumes ou de faibles débits.Finally, we know the experimental laboratory probes called ultrasonic probes well known for example under the name of Sonify (BRANSON) or Vibracell (SONIC'S and MATERIALS). This type of device can handle low volumes or low flow rates.

La présente invention à pour but de proposer un réacteur ultrasonique tubulaire basé sur le principe de la résonnance mécanique pour propager de façon cohérente à partir d'un nombre d'émetteurs réduit des vibrations ultrasoniques destinées au traitement des fluides traversant ledit réacteur.The present invention aims to provide a tubular ultrasonic reactor based on the principle of mechanical resonance to propagate coherently from a reduced number of transmitters ultrasonic vibrations intended for the treatment of fluids passing through said reactor.

Conformément à la présente invention, cet objectif a pu être atteint par la mise au point d'une unité modulaire de réacteur caractérisée en ce qu'elle comprend un corps métallique tubulaire de surface intérieure cylindrique et de section droite circulaire, ouvert à ses deux extrêmités d'alimentation et d'évacuation, en ce que la surface extérieure dudit corps métallique tubulaire présente, au voisinage de la zone nodale, une couronne coaxiale audit tube et faisant saillie radialement, et en ce qu'au moins un convertisseur ultra-sonique est agencé radialement et de façon solidaire de ladite couronne à la périphérie de cette dernière, la fréquence dudit convertisseur étant égale à la fréquence de vibration de ladite couronne et à la fréquence de vibration longitudinale dudit corps métallique tubulaire.In accordance with the present invention, this objective has been achieved by the development of a modular reactor unit characterized in that it comprises a tubular metal body of cylindrical interior surface and of circular cross section, open at its two ends. supply and discharge, in that the outer surface of said tubular metallic body has, in the vicinity of the nodal zone, a ring coaxial with said tube and projecting radially, and in that at least one ultrasonic converter is arranged radially and integral with said ring at the periphery of the latter, the frequency of said converter being equal to the vibration frequency of said ring and to the longitudinal vibration frequency of said tubular metal body.

D'autres caractéristiques et avantages de l'objet de la présente invention apparaîtront à la lecture de la description détaillée faite ci-après notamment en référence aux dessins annexés illustrant un certain nombre de modes de réalisation particuliers, dessins sur lesquels :

  • la figure 1A représente une vue de côté d'une unité modulaire de réacteur selon l'invention,
  • la figure 1B réprésente une vue de face de l'unité modulaire de réacteur de la figure 1A,
  • la figure 2 représente un multi-réacteur en ligne comportant plusieurs unités modulaires de réacteur selon l'invention associé à un convertisseur unique,
  • la figure 3 représente un multi-réacteur en ligne comportant une pluralité d'unités modulaires de réacteur associées à trois convertisseurs distincts,
  • la figure 4 représente un multi-réacteur en ligne comprenant une seule unité modulaire dissymétrique au niveau de la prolongation de la partie tubulaire dudit réacteur,
  • la figure 5 représente un autre mode de réalisation d'un multi-réacteur en ligne associant diverses unités modulaires à plusieurs convertisseurs, et
  • la figure 6 représente une unité modulaire dont la couronne est rapportée sur le corps métallique tubulaire, par exemple par emmanchement à force,
  • la figure 7 représente une unité modulaire utilisant un élément tubulaire intérieur couplé à ladite unité au voisinage des ventres d'amplitude longitudinale (noeud de contrainte).
Other characteristics and advantages of the subject of the present invention will appear on reading the detailed description given below in particular with reference to the appended drawings illustrating a number of particular embodiments, drawings in which:
  • FIG. 1A represents a side view of a modular reactor unit according to the invention,
  • FIG. 1B shows a front view of the modular reactor unit of FIG. 1A,
  • FIG. 2 represents an online multi-reactor comprising several modular reactor units according to the invention associated with a single converter,
  • FIG. 3 represents an online multi-reactor comprising a plurality of modular reactor units associated with three separate converters,
  • FIG. 4 represents an online multi-reactor comprising a single asymmetrical modular unit at the level of the extension of the tubular part of said reactor,
  • FIG. 5 represents another embodiment of an online multi-reactor associating various modular units with several converters, and
  • FIG. 6 represents a modular unit, the crown of which is attached to the tubular metal body, for example by force fitting,
  • FIG. 7 represents a modular unit using an internal tubular element coupled to said unit in the vicinity of the bellies of longitudinal amplitude (constraint node).

Tel que représenté sur les figures 1A et 1B illustrant respectivement une vue de côté et une vue de face de l'unité modulaire de réacteur 10 selon l'invention, on constate que ladite unité est principalemement constituée de trois éléments caractéristiques essentiels. L'unité 10 comprend tout d'abord un corps métallique tubulaire 12 présentant une surface intérieure 14 cylindrique et de section droite circulaire. Le corps métallique tubulaire 12 est ouvert à ses deux extrêmités, c'est-à-dire respectivement à son extrêmité d'alimentation 16 et à son extrêmité d'évacuation 18. Le flux des matières et/ou des réactifs à traiter s'écoule donc dans le sens de la flêche allant de l'extrêmité 16 vers l'extrêmité 18. Ces deux extrêmités d'alimentation et d'évacuation 16, 18 seront associées à des conduits d'alimentation et d'évacuation eux-mêmes éventuellement munis de pompes de circulation. Le reste de l'installation n'est pas représenté étant donné qu'il fait appel à des organes tout à fait classiques bien connus de l'homme du métier.As shown in FIGS. 1A and 1B respectively illustrating a side view and a front view of the modular reactor unit 10 according to the invention, it can be seen that said unit mainly consists of three essential characteristic elements. The unit 10 firstly comprises a tubular metallic body 12 having an inner surface 14 which is cylindrical and of circular cross section. The tubular metal body 12 is open at its two ends, that is to say respectively at its supply end 16 and at its discharge end 18. The flow of the materials and / or of the reagents to be treated flows therefore in the direction of the arrow going from the end 16 towards the end 18. These two supply and discharge ends 16, 18 will be associated with supply and discharge conduits themselves possibly provided with circulation pumps. The rest of the installation is not shown since it uses entirely conventional members well known to those skilled in the art.

L'unité modulaire 10 comprend également sur la surface extérieure du corps métallique tubulaire 12, au voisinage de la zone nodale de cette dernière, une couronne 20 coaxiale audit tube, ladite couronne faisant radialement saillie vers l'extérieur de la surface libre du corps tubulaire 12.The modular unit 10 also comprises, on the external surface of the tubular metallic body 12, in the vicinity of the nodal zone of the latter, a ring 20 coaxial with said tube, said ring projecting radially outwards from the free surface of the tubular body 12.

Enfin, l'unité modulaire 10 comprend au moins un convertisseur ultra-sonique 22 qui est agencé radialement et de façon solidaire de ladite couronne 20 à la périphérie de cette dernière. Conformément à la présente invention la fréquence dudit convertisseur 22 est égale à la fréquence de vibration de ladite couronne 20 et à la fréquence de vibration longitudinale du corps métallique tubulaire 12.Finally, the modular unit 10 comprises at least one ultra-sonic converter 22 which is arranged radially and integral with said crown 20 at the periphery of the latter. In accordance with the present invention, the frequency of said converter 22 is equal to the frequency of vibration of said ring 20 and to the frequency of longitudinal vibration of the tubular metallic body 12.

Dans la pratique on utilise comme convertisseur ultra-sonique 22 un convertisseur classique, par exemple du type à excitation piezoélectrique. Il peut par exemple être du type "Triplet de Langevin" tel que cela se trouve décrit dans l'ouvrage High Intensity Ultrasonics de B. BROWN et J.E. GOODMAN.In practice, a conventional converter, for example of the piezoelectric excitation type, is used as the ultrasonic converter 22. It can for example be of the "Langevin Triplet" type as described in the book High Intensity Ultrasonics by B. BROWN and J.E. GOODMAN.

Sur le mode de réalisation particulier décrit et représenté aux figures 1A et 1B, la couronne coaxiale 20 est usinée dans la masse du corps métallique tubulaire 12. Dans ce type de réalisation, la couronne 20 se raccorde à la surface extérieure du corps tubulaire 12 par l'intermédiaire de congés de raccordement 24. On observera que le corps métallique tubulaire 12 présente, sur le mode de réalisation décrit, une longueur égale à une demi-longueur d'onde pour la fréquence que l'on désire utiliser. Il est à noter à ce propos que la fréquence de la vibration ultra-sonique délivree par l'émetteur ou le convertisseur 22 sera généralement comprise entre 5 et 100 kHz. Dans ce mode de réalisation particulier la longueur du corps métallique tubulaire est rigoureusement égale à une demi longueur d'onde de la fréquence de la vibration ultra-sonique. Il est cependant parfaitement possible, dans le cadre de la présente invention, d'avoir recours à une partie métallique tubulaire de plus grande dimension, se prolongeant par exemple d'un ou des deux côtés de la couronne coaxiale 20 par une longueur égale à un multiple entier de demi longueur d'onde de la fréquence délivrée, la liaison de cette partie métallique avec l'unité modulaire pouvant par exemple être réalisée au niveau des ventres d'amplitude longitudinaux (noeuds de contraintes) au moyen de filetages. emmanchements à force, soudures ou analogue ou bien encore être usinee dans la masse.In the particular embodiment described and shown in FIGS. 1A and 1B, the coaxial ring 20 is machined in the mass of the tubular metal body 12. In this type of embodiment, the ring 20 is connected to the external surface of the tubular body 12 by via connection leave 24. It will be observed that the tubular metallic body 12 has, on the embodiment described, a length equal to half a wavelength for the frequency which it is desired to use. It should be noted in this connection that the frequency of the ultrasonic vibration delivered by the transmitter or the converter 22 will generally be between 5 and 100 kHz. In this particular embodiment, the length of the tubular metal body is strictly equal to half a wavelength of the frequency of the ultrasonic vibration. It is however perfectly possible, in the context of the present invention, to use a larger tubular metal part, extending for example from one or both sides of the coaxial ring 20 by a length equal to one integer multiple of half wavelength of the delivered frequency, the connection of this metallic part with the modular unit can for example be carried out at the level of the stomachs of longitudinal amplitude (stress nodes) by means of threads. press fittings, welds or the like or else be machined in the mass.

On rappellera à ce propos que les diamètres intérieur et extérieur de la couronne 20, le diamètre intérieur de la couronne 20 correspondant par ailleurs au diamètre intérieur du corps métallique tubulaire 12, déterminent la fréquence radiale de cette couronne coaxiale 20. En revanche la longueur du corps métallique tubulaire 12 que l'on choisit en multiple de demi longueur d'onde détermine la fréquence longitudinale de l'ensemble du réacteur.In this connection, it will be recalled that the inside and outside diameters of the crown 20, the inside diameter of the crown 20 moreover corresponding to the internal diameter of the tubular metallic body 12, determine the radial frequency of this coaxial crown 20. On the other hand, the length of the tubular metallic body 12 which is chosen as a multiple of half wavelength determines the longitudinal frequency of l whole reactor.

Dans le mode de réalisation particulier décrit aux figures 1A et 1B on utilise un seul convertisseur ou émetteur 22 qui peut être indifféremment du type électrostrictif, magnétostrictif, électrocapacitif, ou encore plus habituellement piézo-électrique . Le convertisseur 22 est fixé à la périphérie de la couronne 20 de préférence au niveau d'un méplat 26 agencé de manière à assurer une parfaite mise en contact de l'émetteur 22 avec la couronne 20. La liaison mécanique entre ces deux organes est notamment assurée de façon avantageuse par l'intermédiaire d'un goujon ou organe analogue 28.In the particular embodiment described in FIGS. 1A and 1B, a single converter or transmitter 22 is used which can be either of the electrostrictive, magnetostrictive, electrocapacitive, or even more usually piezoelectric type. The converter 22 is fixed to the periphery of the crown 20 preferably at the level of a flat 26 arranged so as to ensure perfect contacting of the transmitter 22 with the crown 20. The mechanical connection between these two members is in particular advantageously provided by means of a stud or the like 28.

En ce qui concerne la fréquence de la vibration ultra-sonique délivrée par le convertisseur 22 de l'unité modulaire de réacteur 10 selon l'invention il y a lieu de préciser que les diamètres intérieurs et extérieurs respectivement di et de de la couronne 20 peuvent être déterminés de façon classique par l'homme du métier en relation avec ladite fréquence de vibration délivrée par l'émetteur. Dans le cas d'une couronne 20 présentant par exemple une épaisseur de l'ordre de 15 mm, les diamètres intérieurs et extérieurs de cette dernière sont déterminés en fonction de la fréquence de vibration F conformément à la relation :

Figure imgb0001

où C représente la vitesse du son, en cm par seconde, associée au metal dans lequel est réalisée ladite couronne 20.With regard to the frequency of the ultrasonic vibration delivered by the converter 22 of the modular reactor unit 10 according to the invention, it should be noted that the interior and exterior diameters d i and d e of the crown respectively 20 can be conventionally determined by a person skilled in the art in relation to said vibration frequency delivered by the transmitter. In the case of a crown 20 having for example a thickness of the order of 15 mm, the inside and outside diameters of the latter are determined as a function of the vibration frequency F in accordance with the relation:
Figure imgb0001
where C represents the speed of sound, in cm per second, associated with the metal in which said crown 20 is produced.

On peut citer par exemple une couronne réalisée en alliage d'aluminium excitée à partir d'un émetteur piézoélectrique 2O kHz ce diamètre 40 mm. Dans ce cas de figure la couronne aura une épaisseur de 30 mm, un diamètre extérieur de 130 mm pour un diamètre intérieur de 42 mm pour respecter la fréquence de 20 kHz délivrée par l'émetteur.We can cite for example a crown made of alloy aluminum excited from a 2O kHz piezoelectric transmitter with a diameter of 40 mm. In this case the crown will have a thickness of 30 mm, an outside diameter of 130 mm for an inside diameter of 42 mm to respect the frequency of 20 kHz delivered by the transmitter.

Une telle unité de réacteur fonctionne de la manière suivante. La vibration produite par le ou par les convertisseur(s) 22 provoque la mise en vibration radiale de la couronne 20, qui, en même temps, provoque la mise en vibration longitudinale de la partie tubulaire en multiple de demi longueur d'onde du corps métallique tubulaire 12. La phase de compression de la couronne 20 correspond à la phase de dilatation longitudinale du corps tubulaire 12, et la dilatation de la couronne 20 correspond à la phase de compression longitudinale du corps tubulaire 12. Pour obtenir un tel résultat on rappellera que la couronne coaxiale 20 doit être située au voisinage du plan nodal du corps tubulaire 12. Ainsi, le réacteur selon l'invention utilise la vibration radiale du diamètre intérieur de la couronne 20 pour mettre en cavitation un liquide quelconque à traiter, qui se trouve débité en continu au travers du diamètre intérieur du corps tubulaire métallique 12.Such a reactor unit operates in the following manner. The vibration produced by the converter (s) 22 causes the crown 20 to vibrate radially, which, at the same time, causes the tubular part to vibrate longitudinally in multiples of half the wavelength of the body tubular metal 12. The compression phase of the crown 20 corresponds to the longitudinal expansion phase of the tubular body 12, and the expansion of the crown 20 corresponds to the longitudinal compression phase of the tubular body 12. To obtain such a result, it will be recalled that the coaxial ring 20 must be located in the vicinity of the nodal plane of the tubular body 12. Thus, the reactor according to the invention uses the radial vibration of the internal diameter of the ring 20 to cavitate any liquid to be treated, which is found continuously delivered through the internal diameter of the metallic tubular body 12.

Ainsi, tout liquide, tout gaz, tout colloïde ou encore toute autre matière à traiter doivent être par des moyens classiques non représentés débités au travers du diamètre intérieur 14 du corps métallique tubulaire 12 du réacteur 10.Thus, any liquid, any gas, any colloid or any other material to be treated must be by conventional means, not shown, delivered through the internal diameter 14 of the tubular metallic body 12 of the reactor 10.

La figure 2 représente un réacteur ultra-sonique qui est obtenu par coupage en série d'une pluralité d'unités modulaires de réacteur 10 tel que représenté aux figures 1A et 1B. Dans le mode de réalisation de la figure 2, on a regroupé trois unités modulaires 10 de manière à former un multi-réacteur en ligne, mais en n'utilisant qu'un seul convertisseur ultra-sonique 22. Ainsi un tel ensemble peut être réalisé monobloc ou par liaisons rigides desdites unités modulaires au niveau des ventres d'amplitude longitudinaux.FIG. 2 represents an ultrasonic reactor which is obtained by cutting in series a plurality of modular reactor units 10 as shown in FIGS. 1A and 1B. In the embodiment of FIG. 2, three modular units 10 have been grouped together so as to form an online multi-reactor, but using only a single ultrasonic converter 22. Thus such an assembly can be produced in one piece or by rigid connections of said modular units at the level of the stomachs of longitudinal amplitude.

Il est également possible, tel que cela se trouve illustre à la figure 3 de réaliser un multi-réacteur en ligne par association de plusieurs unités modulaires de réacteur 10 couplées à une pluralité de convertisseurs 22. Dans le mode de réalisation particulier décrit, on utilise trois unités modulaires complètes équipées chacune de leur convertisseur 22, ces unités complètes étant disposées aux deux extrêmités et au centre du réacteur tubulaire. On observera qu'entre chacune de ces unités modulaires 10 complètes en demi longueur d'onde, on a interposé un ensemble constitué par un corps métallique tubulaire 12 également en demi longueur d'onde se prolongeant à sa périphérie par une couronne coaxiale 22. Ceci revient également à une association d'unités modulaires de réacteur précédemment décrites dont certaines sont en demi longueur d'onde et d'autres en longueur d'onde entière.It is also possible, as illustrated in FIG. 3, to produce an online multi-reactor by association of several modular reactor units 10 coupled to a plurality of converters 22. In the particular embodiment described, three complete modular units are used, each equipped with their converter 22, these complete units being arranged at the two ends and in the center of the tubular reactor. It will be observed that between each of these modular units 10 complete at half wavelength, there is interposed an assembly constituted by a tubular metallic body 12 also at half wavelength extending at its periphery by a coaxial ring 22. This also comes from an association of modular reactor units described above, some of which are half wavelength and others are full wavelength.

Le fonctionnement de ce type de réacteur en ligne est identique au fonctionnement des unités modulaires précédemment décrites. Dans la même phase du mouvement vibratoire, on observera donc pour les différents éléments associés des états simultanés, de proche en proche, en compression et en dilatation.The operation of this type of in-line reactor is identical to the operation of the modular units previously described. In the same phase of the vibratory movement, we will therefore observe for the different associated elements simultaneous states, step by step, in compression and expansion.

Lorsque le réacteur ultra-sonique en ligne comprend plusieurs émetteurs ou convertisseurs ultra-soniques 22, ces derniers peuvent être avantageusement alimentés en parallèle par un même générateur. Il convient cependant de prendre la précaution d'inverser la polarité des émetteurs de rang pair par rapport aux émetteurs de rang impair, ceci dans le but de respecter les inversions de phases qui se produisent à chaque demi longueur d'onde.When the online ultrasonic reactor comprises several ultrasonic transmitters or converters 22, the latter can advantageously be supplied in parallel by the same generator. However, care should be taken to reverse the polarity of the emitters of even rank with respect to the emitters of odd rank, this in order to respect the phase inversions that occur at each half wavelength.

Le mode de réalisation particulier représenté à la figure 4 comprend une couronne radiale 20 qui va exciter en série une longueur de corps métallique tubulaire prolongeant la partie tubulaire de l'élément modulaire central de part et d'autre de ce dernier. On observera que la longueur des tubes de chacun des deux côtés de l'unité modulaire centrale est également réalisée en un multiple entier de demi longueur d'onde. Les dits tubes peuvent par exemple être vissés ou emmanchés à force à l'unité modulaire au niveau des ventres d'amplitude longitudinaux. Il n'est pas nécessaire d'avoir recours à une disposition symétrique. Tel que cela se trouve illustré à la figure 4, il peut être avantageux en fonction des applications particulières envisagées de prévoir une zone tubulaire plus ou moins longue en amont ou en aval de la zone de vibration ultra-sonique intense. Dans la pratique, on aura recours à un multiple de demi longueur d'onde généralement compris entre 1 et 10, multiple choisi en fonction du matériau dans lequel on réalise le réacteur, en fonction des produits à traiter et bien sûr, de la nature et des conditions de la réaction mise en jeu au sein du réacteur. Il peut par exemple être avantageux, comme cela se trouve illustré sur la figure 4, de prévoir une entrée d'alimentation relativement proche de la zone intense de cavitation, ce qui permet de communiquer rapidement l'énergie nécessaire à l'initiation de la réaction qui peut se prolonger dans la partie tubulaire avale du réacteur, i.e. dans une zone soumise à une cavitation ultra-sonique de moins grande puissance et de moins grande amplitude.The particular embodiment represented in FIG. 4 comprises a radial crown 20 which will excite in series a length of tubular metallic body extending the tubular part of the central modular element on either side of the latter. It will be observed that the length of the tubes on each of the two sides of the central modular unit is also produced in an integer multiple of half wavelength. Said tubes can for example be screwed or force-fitted to the modular unit at the level of the bellies of longitudinal amplitude. He is not necessary to have recourse to a symmetrical arrangement. As illustrated in FIG. 4, it may be advantageous, depending on the particular applications envisaged, to provide a more or less long tubular zone upstream or downstream of the zone of intense ultrasonic vibration. In practice, we will use a multiple of half wavelength generally between 1 and 10, multiple chosen according to the material in which the reactor is made, according to the products to be treated and of course, the nature and conditions of the reaction involved in the reactor. It may for example be advantageous, as illustrated in FIG. 4, to provide a supply inlet relatively close to the intense cavitation zone, which makes it possible to rapidly communicate the energy necessary for the initiation of the reaction. which can extend into the downstream tubular part of the reactor, ie in an area subjected to ultra-sonic cavitation of less power and less amplitude.

L'homme du métier choisira, en fonction de l'application particulière, la longueur adaptée dudit corps métallique tubulaire 12 en respectant toutefois une longueur égale à un multiple entier de demi longueurs d'onde de la fréquence de la vibration ultra-sonique délivrée par le ou les convertisseurs 22.A person skilled in the art will choose, depending on the particular application, the suitable length of said tubular metallic body 12 while respecting a length equal to an integer multiple of half wavelengths of the frequency of the ultrasonic vibration delivered by the converter (s) 22.

La figure 5 illustre un dernier mode de réalisation dans lequel on a recours à plusieurs couronnes radiales 20 qui vont exciter en serie une longueur de tube qui, en l'espèce est en demi longueur d'onde, mais qui bien entendu peut également être constitué par de plus grandes longueurs de tubes réalisées en multiple entier de demi longueurs d'onde. Le principe de fonctionnement reste rigoureusement identique.FIG. 5 illustrates a final embodiment in which several radial rings 20 are used which will serially excite a length of tube which, in this case is at half wavelength, but which of course can also be formed by greater lengths of tubes produced as an integer multiple of half wavelengths. The operating principle remains strictly identical.

La figure 6 représente une variante d'une unité modulaire de réacteur selon l'invention. Conformément à cette variante, au lieu d'être usinée dans la masse, la couronne coaxiale 20 et le corps tubulaire métallique 12 sont réalisés séparément. Ceci permet de choisir un matériau d'excellente propriété accoustique tel qu'un alliage d'aluminium et/ou de titane, pour la fabrication de la couronne 20, et d'avoir recours à un autre matériau présentant une plus grande résistance à l'érosion de cavitation ultra-sonique pour la fabrication de la partie tubulaire métallique 12 à l'intérieur de laquelle circule le liquide à traiter. On pourra ainsi réaliser la partie tubulaire 12 en un acier spécial tel qu'un acier inoxydable. En outre, la surface intérieure 14 du réacteur tubulaire sera avantageusement munie d'une couche de protection contre l'érosion par cavitation, par exemple d'une couche céramique, métallique dure ou encore céramométallique. Dans ce mode de réalisation de la figure 6, la couronne est rendue solidaire de la partie tubulaire par un moyen mécanique approprié assurant une liaison solide et homogène. Une telle liaison rigide absolument indispensable pour réaliser l'unité modulaire de reacteur selon l'invention, peut par exemple être obtenue par des moyens mécaniques tels qu'un vissage, un blocage, ou encore un emmanchement à force. On peut également avoir recours à d'autres moyens non mécaniques, tels que des collages, soudages ou analogues.

  • La figure 7 représente une autre variante d'une unité modulaire de réacteur selon l'invention.
FIG. 6 represents a variant of a modular reactor unit according to the invention. According to this variant, instead of being machined in the mass, the coaxial ring 20 and the metallic tubular body 12 are produced separately. This makes it possible to choose a material with excellent acoustic properties such as an aluminum alloy and / or titanium, for the manufacture of the crown 20, and to have recourse to another material having a greater resistance to the ultrasonic cavitation erosion for the manufacture of the metallic tubular part 12 inside which circulates the liquid to be treated. We can thus realize the tubular part 12 in a special steel such as stainless steel. In addition, the inner surface 14 of the tubular reactor will advantageously be provided with a layer for protection against erosion by cavitation, for example with a ceramic, hard metallic or even ceramometallic layer. In this embodiment of FIG. 6, the crown is made integral with the tubular part by an appropriate mechanical means ensuring a solid and homogeneous connection. Such a rigid connection, absolutely essential for producing the modular reactor unit according to the invention, can for example be obtained by mechanical means such as screwing, blocking, or even force fitting. One can also use other non-mechanical means, such as bonding, welding or the like.
  • FIG. 7 represents another variant of a modular reactor unit according to the invention.

Conformément à cette variante, l'unité modulaire de réacteur est agencée de manière à recevoir à l'intérieur un élément tubulaire 30 accordé à la fréquence de l'émetteur 22, vibrant à partir du mode axial par serrage de ses deux extrémités 32,34 au voisinage des ventres d'amplitude (noeuds de contraintes) longitudinale de ladite unité.According to this variant, the modular reactor unit is arranged so as to receive inside a tubular element 30 tuned to the frequency of the transmitter 22, vibrating from the axial mode by clamping its two ends 32,34 in the vicinity of the bellies of amplitude (constraint nodes) longitudinal of said unit.

Dans ce mode de réalisation, ledit élément tubulaire 30 est serré entre deux pièces elles-mêmes accordées à la fréquence de l'émetteur et pouvant être, par exemple, des corps métalliques tubulaires 36 et 38 tels que décrits sur la figure 4.In this embodiment, said tubular element 30 is clamped between two pieces which are themselves tuned to the frequency of the transmitter and which can be, for example, tubular metallic bodies 36 and 38 as described in FIG. 4.

L'élément tubulaire rapporté 30, sera avantageusement agencé avec des portées soignées (i.e. 45°) pour assurer un parfait centrage et un bon couplage avec les éléments 36 et 38 le serrant à chacune de ses extrémités 32 et 34. On notera, tel que décrit sur la figure 7, un jeu 40 avec le diamètre intérieur de l'unité modulaire permettant les libres expansion et compression radiales de l'élément tubulaire 30 à l'intérieur duquel circule le fluide à traiter.The added tubular element 30 will advantageously be arranged with neat spans (ie 45 °) to ensure perfect centering and good coupling with the elements 36 and 38 clamping it at each of its ends 32 and 34. It will be noted, such that described in FIG. 7, a set 40 with the internal diameter of the modular unit allowing the free radial expansion and compression of the tubular element 30 inside which the fluid to be treated circulates.

Ainsi, les unités modulaires de réacteur selon l'invention, peuvent être utilisées pour le traitement de tous types de liquide, gaz, colloïde, etc. débitant de façon naturelle ou forcée à travers le diamètre intérieur des réacteurs. Il convient également de noter qu'un flux de liquide extérieur pourraît être simultanément traité par la cavitation provoqué par la vibration extérieure des couronnes 20, c'est-à-dire que l'on pourrait traiter simultanément deux flux de liquides différents, l'un passant à l'intérieur du réacteur, l'autre s'écoulant à la périphérie extérieure.Thus, the modular reactor units according to the invention can be used for the treatment of all types of liquid, gas, colloid, etc. naturally or forced flow through the inside diameter of the reactors. It should also be noted that an external liquid flow could be simultaneously treated by the cavitation caused by the external vibration of the crowns 20, that is to say that two different liquid flows could be treated simultaneously, the one passing inside the reactor, the other flowing at the outer periphery.

Les applications industrielles de ce type de réacteurs sont nombreuses : on citera par exemple à titre d'illustration les applications suivantes :

  • activations de réactions chimiques (Grignard, Barbier, etc.)
  • désagglomération et lavage de poudres métalliques, céramiques ou minérales
  • traitement de minerals
  • mouillage et dispersions de pigments, colorants
  • dissolution accélérée de gaz
  • dégazage
  • homogénéisation de produits
  • nettoyage de fils
  • émulsification, etc.
The industrial applications of this type of reactor are numerous: the following applications will be cited for example:
  • activation of chemical reactions (Grignard, Barber, etc.)
  • deagglomeration and washing of metallic, ceramic or mineral powders
  • mineral processing
  • wetting and dispersion of pigments, dyes
  • accelerated gas dissolution
  • degassing
  • product homogenization
  • wire cleaning
  • emulsification, etc.

Claims (9)

  1. Modular reactor unit for continuous ultrasonic treatment of materials and/or reagents characterized in that it comprises a tubular metal body (12) having a cylindrical interior surface (14) and a circular transverse cross-section open at a feed end (26) and a discharge end (18), in that the exterior surface of said tubular metal body has in the vicinity of the nodal zone a radially projecting collar (20) coaxial with said tube, and in that at least one ultrasonic converter (22) is disposed radially and attached to said collar at its periphery, and in that the length of said tubular metal body (12) is equal to an integer multiple of half the wavelength at the frequency of ultrasonic vibration emitted by said converter (22), the inside and outside diameters of the collar (20) being such that the frequency of vibration of said collar is also equal to the frequency of ultrasonic vibration emitted by the converter (22).
  2. Modular reactor unit according to claim 1 characterized in that said ultrasonic converter (22) is fixed to the periphery of said collar (20) at a flat adapted to ensure perfect coupling of the converter (26) and the collar, the mechanical coupling being provided by a pin (28) or the like.
  3. Modular reactor unit according to claim 1 or claim 2 characterized in that said collar (20) is machined in one piece with the tubular metal body (12).
  4. Modular reactor unit according to claim 1 or claim 2 characterized in that said collar (20) is attached to said tubular metal body (12) by any means providing a rigid coupling.
  5. Modular reactor unit according to claim 4 characterized in that said collar (20) is made from a metal having good acoustical properties such as aluminum and/or titanium alloy and in that said tubular metal body (12) is made from a metal having a good resistance to erosion caused by cavitation such as stainless steel.
  6. Modular reactor unit according to any one of claims 1 to 5 characterized in that the interior surface (14) of the tubular reactor has a ceramic, hard metal or combined ceramic/metal coating to protect it against erosion by cavitation.
  7. Modular reactor unit according to any one of claims 1 to 4 characterized in that a tubular member (30) is attached to the interior of said unit by clamping means in the vicinity of longitudinal maximum amplitude regions of said unit.
  8. Ultrasonic reactor characterized in that it comprises a series coupling of a plurality of modular reactor units (10) according to any one claims 1 to 7 to create an in-line multireactor.
  9. Ultrasonic reactor according to claim 8 characterized in that it comprises a plurality of converters (22) fed in parallel by the same generator.
EP92904795A 1991-01-17 1992-01-15 Modular unit for a tubular ultrasonic reactor Expired - Lifetime EP0567579B1 (en)

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FR9100499A FR2671737A1 (en) 1991-01-17 1991-01-17 MODULAR TUBULAR ULTRA-SONIC REACTOR UNIT.
FR9100499 1991-01-17
PCT/FR1992/000029 WO1992012790A1 (en) 1991-01-17 1992-01-15 Modular unit for a tubular ultrasonic reactor

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Families Citing this family (23)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
FR2686805A1 (en) * 1992-02-04 1993-08-06 Kodak Pathe DEVICE FOR DISSOLVING GASEOUS BUBBLES CONTAINED IN A LIQUID COMPOSITION USED IN PARTICULAR FOR PHOTOGRAPHIC PRODUCTS.
FR2708873B1 (en) * 1993-08-11 1995-12-08 Transbiotech Method for washing granular and / or particulate materials.
GB2285142B (en) * 1993-10-16 1997-12-17 Rawson Francis F H Fluid processing
GB2306202B (en) * 1995-10-05 1999-04-14 British Nuclear Fuels Plc An ultrasonic apparatus
DE19539533A1 (en) 1995-10-24 1997-04-30 Basf Ag Apparatus for sound treatment of products
GB9701797D0 (en) * 1997-01-29 1997-03-19 Univ Coventry Cavitation inducer
FR2776945B1 (en) * 1998-04-06 2000-06-16 Cs Systemes De Securite 3Cs PROCESS FOR DEAGGREGATION OR DEAGGLOMERATION OF PARTICULATE CLUSTERS, PROCESS FOR PREPARING CONCRETE OR MORTAR AND CONCRETE OR MORTAR THUS OBTAINED
CA2238951A1 (en) 1998-05-26 1999-11-26 Les Technologies Sonomax Inc. Acoustic cavitation reactor for the processing of materials
FR2793811B1 (en) * 1999-05-17 2002-01-11 R V X CEMENTING PROCESS, REACTOR FOR CARRYING OUT SAID METHOD AND INSTALLATION COMPRISING SUCH A REACTOR
FR2822084B1 (en) * 2001-03-13 2003-12-12 Sodeva LIQUID AND CONTINUOUS FILTERING DEVICE USING HIGH POWER DENSITY ULTRASOUND
GB0106483D0 (en) * 2001-03-16 2001-05-02 Ws Atkins Consultants Ltd Improvemnts relating to fluid processing devices
IL149932A0 (en) * 2002-05-30 2002-11-10 Nano Size Ltd High power ultrasonic reactor and process for ultrasonic treatment of a reaction material
US6786383B2 (en) * 2002-11-14 2004-09-07 Kimberly-Clark Worldwide, Inc. Ultrasonic horn assembly with fused stack components
US7224103B2 (en) * 2004-09-01 2007-05-29 Impulse Devices, Inc. Acoustic driver assembly with recessed head mass contact surface
CA2539054A1 (en) * 2006-03-09 2007-09-09 Nicholas A. Tomory A sonofusion device and method of operating the same
US8197763B2 (en) * 2006-09-13 2012-06-12 University Of Southern California Ultrasound-assisted oxidative desulfurization of diesel fuel using quaternary ammonium fluoride and portable unit for ultrasound-assisted oxidative desulfurization
DE102008007276B4 (en) * 2008-02-01 2014-02-06 Scheugenpflug Ag vent adapter
WO2009115543A1 (en) * 2008-03-19 2009-09-24 Erminio Diolaiti Method an device for ultrasonic treatment of a fluid
EP2223742B1 (en) * 2009-02-06 2012-05-02 BANDELIN electronic GmbH & Co. KG Fluid reactor
US9502632B2 (en) 2011-05-17 2016-11-22 Dr. Hielscher Gmbh Resonator for the distribution and partial transformation of longitudinal vibrations and method for treating at least one fluid by means of a resonator according to the invention
US9114426B2 (en) * 2011-11-02 2015-08-25 Dr. Hielscher Gmbh Ultrasonic generator with a resonator having a clamping opening
JP6327789B2 (en) * 2013-03-06 2018-05-23 株式会社タイセー Ultrasonic reactor
IT201700042440A1 (en) 2017-04-18 2018-10-18 Ecotecne S R L MODULAR STRUCTURE OF APPLIANCE FOR THE TREATMENT OF FLUIDS WITH ULTRASOUND AND GROUP OF STRUCTURES FOR SUCH TREATMENT

Family Cites Families (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4074152A (en) * 1974-09-30 1978-02-14 Kabushiki Kaisha Toyota Chuo Kenkyusho Ultrasonic wave generator
US4069433A (en) * 1976-06-03 1978-01-17 Westinghouse Electric Corporation Modular transducer assembly
FR2354827A1 (en) * 1976-06-16 1978-01-13 Mecasonic Sa ULTRA-SOUND-PRODUCING DEVICE THAT CAN BE USED IN PARTICULAR IN THE THERMOPLASTIC MATERIALS INDUSTRY
US4347110A (en) * 1980-07-10 1982-08-31 Scm Corporation Method for tall oil recovery and apparatus therefor
US4392380A (en) * 1981-02-11 1983-07-12 The United States Of America As Represented By The United States Department Of Energy High temperature pressure coupled ultrasonic waveguide
US4339247A (en) * 1981-04-27 1982-07-13 Battelle Development Corporation Acoustic degasification of pressurized liquids
US4433916A (en) * 1982-11-02 1984-02-28 Hall Mark N Acoustic resonator having transducer pairs excited with phase-displaced energy
JP2644730B2 (en) * 1986-03-24 1997-08-25 株式会社日立製作所 Micro fluid transfer device

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ATE125464T1 (en) 1995-08-15
JPH06504483A (en) 1994-05-26
DK0567579T3 (en) 1995-12-27
US5384508A (en) 1995-01-24
AU1253392A (en) 1992-08-27
ES2077400T3 (en) 1995-11-16
JP3278846B2 (en) 2002-04-30
WO1992012790A1 (en) 1992-08-06
CA2100571C (en) 2002-04-30
DE69203717T2 (en) 1996-03-14
DE69203717D1 (en) 1995-08-31
CA2100571A1 (en) 1992-07-18
FR2671737A1 (en) 1992-07-24
AU657947B2 (en) 1995-03-30
FR2671737B1 (en) 1994-12-16
EP0567579A1 (en) 1993-11-03

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